Photochromic substrate container

ABSTRACT

A semiconductor wafer, substrate, or reticle storage or shipping device that includes a photochromic indicator of exposure to undesired electromagnetic radiation. The present invention includes the incorporation of a photochromic material into the plastic used to fabricate at least a portion of a semiconductor wafer, disk, or reticle shipping or storage containers. The container may include photochromic material in the form of a transparent window or a larger portion of the container. The photochromic material may change color or darkness in response to exposure to a selected range of wavelengths of light.

This application claims the benefit of U.S. Provisional Application Ser.No. 60/514,164 filed Oct. 24, 2003, the same being incorporated hereinby reference.

FIELD OF THE INVENTION

The invention relates to wafers containers for transport, shipping andstorage of substrates.

BACKGROUND OF THE INVENTION

During processing semi-conductor wafers are subjected to numerousprocess steps in various machines and at various locations. The wafersmust be transported from workstation to workstation and from facility tofacility to accomplish these various steps. Numerous types of shippingdevices are known for handling storing and shipping semi-conductorwafers. In general, such devices hold the wafers in axially alignedarrays. Where wafers are shipped from facility to facility the wafersmay be exposed to sunlight for significant periods of time. Sunlightincludes substantial amounts of electromagnetic radiation in theultraviolet wavelengths. Wafer containers may also be exposed toultraviolet light from other sources.

Current, state of the art, semi-conductor lithography productionprocesses use deep ultraviolet lasers to image circuits with criticalfeatures ranging in size as small as one hundred thirty to one hundredfifty nanometers. It is expected that in the near future criticalfeatures may shrink to a size range of about seventy nanometers.

In the production process wafers are spin coated with a photoresist. Thephotoresist is then baked to adhere it to the wafer. Next, an image ofthe desired circuitry is projected onto the wafer using electromagneticradiation. Today, this is commonly deep ultraviolet radiation from alaser. The photoresist material is chemically altered by exposure toultraviolet light to create either a negative or positive image of thecircuit depending on the process used. The undesired photoresistmaterial is then etched away leaving an integrated circuit pattern onthe wafer.

As discussed above, photoresists that are used in semi-conductorprocesses are sensitive to light in the ultraviolet wavelengths. Becauseof the tiny size of the critical elements of modern integrated circuitsonly a very small exposure to uncontrolled ultraviolet radiation canlead to spoilage of a wafer. Consequently, it is desirable, in theproduction process, that photoresists only be exposed to the ultravioletwave lengths of light under carefully controlled conditions. Unintendedexposure will destroy the usability of wafers exposed.

Thus, wafer shipping containers used in the handling, storing andshipping of wafers are made of materials, typically plastics, that blockultraviolet light to prevent it from affecting wafers coated withphotoresist material. It is also desirable that wafer shippingcontainers be, at least partially transparent to visible light to allowworkers to determine whether a shipping container is empty or full.Thus, shipping containers have been made of materials that aretransparent, at least in part, to visible light but that are relativelyopaque to ultraviolet light.

Nonetheless, ultraviolet blocking is never absolute and it is desirableto expose wafer containers to ultraviolet radiation as little aspossible. Thus, it would be a benefit to the semiconductor industry ifwafer containers themselves could signal to workers that the wafercontainer was currently exposed to ultraviolet radiation. This wouldsignal the worker to move the wafer container to an ultravioletsheltered location.

Additionally, similar issues exist with regard to the storage andprocessing the disks for computer hard drives and the reticles for thelithography operations.

SUMMARY OF THE INVENTION

The present invention solves the above problem by providing asemiconductor wafer, substrate, or reticle storage or shipping devicethat includes a photochromic indicator of ultraviolet exposure.

Photochromic materials darken when exposed to sunlight or another sourceof ultraviolet radiation. Photochromic material transitions between twodifferent states. A low energy state in which the material is clear,uncolored and an activated state in which the material is colored. Whenelectromagnetic radiation of an appropriate energy level impinges on thephotochromic material.

The present invention includes the incorporation of a photochromicmaterial into the plastic used to fabricate semiconductor wafer, disk,or reticle shipping or storage containers.

In operation, the photochromic container is used to transport and storesemiconductor wafers in a similar fashion to any other semiconductorshipping container. However, if the container is left exposed tosunlight or another source of ultraviolet radiation that may, withsufficient time, have an affect on the photoresist layer which issensitive to ultraviolet radiation, the shipping container will darkenin color. This darkening in color will provide an immediate indicationto the shipping workers that the containers are being exposed toultraviolet light and should be removed from the situation as soon aspossible to avoid having a negative affect on the photoresist materials.

It is known in the prior art to introduce organic molecules exhibitingphotochromic properties into a number of light-transmissible articles.

The fabrication of photochromic polymers is known in the polymer arts.Some available options for introducing dyes into a polymer article, suchas a wafer carrier, are, for example: (1) Impregnation or imbibing froma fluid medium contacting the surface of the polymer, (2) Incorporationof the dye in a resin coating applied to the surface; (3) Impregnationor diffusive transfer from a solid or gel in contact with the polymersurface, (4) Dispersion of the dye in the monomer or thermoplastic fromwhich the article is to be fabricated.

In operation, the photochromic container is used to transport and storesemiconductor wafers, disks, or reticles in a similar fashion to anyother known substrate container. However, if the container is leftexposed to sunlight or another source of ultraviolet radiation that may,with sufficient time, have an affect on the photoresist layer which issensitive to ultraviolet radiation, the shipping container will darkenin color. This darkening in color can provide an immediate indication tothe shipping workers that the containers are being exposed toultraviolet light and should be removed from the situation as soon aspossible to avoid having a negative affect on the photoresist materials.Additionally, the darkening in color can provide the functional effectof reducing the UV entering the container.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 depicts an exemplary partially transparent wafer container; and

FIG. 2 depicts an exemplary substantially transparent wafer container.

DETAILED DESCRIPTION OF THE INVENTION

Referring to FIG. 1, a partially transparent wafer container 10generally includes a case 12 and a door 14. Case 12 includes a handle 16for use in carrying and encloses a wafer holder 18. Wafer holder 18 isadapted to support a number of wafers in axially aligned arrays.

In this example, case 12 includes a transparent portion 20 and opaqueportion 22. Preferably, transparent portion 20 is formed of aphotochromic material that will change color or darkness upon expose toultraviolet light. Transparent portion 20 may also be a portion of door14 or a smaller window into wafer container 10.

Referring now to FIG. 2, substantially transparent wafer container 24generally includes a case 26 and a door 28. Wafer container 24 encloseswafer array 30 which includes a plurality of wafers axially arrayed.Either case 26 or door 28 may support handle 32. In this exemplaryembodiment, wafer container 24 is substantially transparent throughout alarge portion of its construction. At least a portion of wafer container24 is made from a photochromic material that changes color or darknessin response to exposure to ultraviolet light.

In operation, partially transparent wafer container 10 or substantiallytransparent wafer container 24 are used to transport wafers between worksites. If either partially transparent wafer container 10 orsubstantially transparent wafer container 24 are exposed to ultravioletlight for a significant period of time, the photochromic portions of thecontainers will darken or change color to signal this to the workershandling the containers. Thus, a worker having received this readilyobvious signal indicating exposure to ultraviolet light can alter thelocation of the containers in order to prevent signification ultravioletexposure leading to harm of the wafers or the darkening itself mayreduce the entry UV radiation and prevent or minimize damage to thesubstrate or reticles.

The invention includes photochromatic materials in reticle carriers.Reticle carriers are illustrated in U.S. Pat. Nos. 6,513,654 and6,216,873 which are incorporated by reference. Similarly, the inventionincludes disk shippers such as illustrated in U.S. Pat. Nos. 4,557,382and 5,253,755 and incorporated herein by reference.

The present invention may be embodied in other specific forms withoutdeparting from the central attributes thereof, therefore, theillustrated embodiments should be considered in all respects asillustrative and not restrictive, reference being made to the appendedclaims rather than the foregoing description to indicate the scope ofthe invention.

1. A carrier for transporting articles including semiconductor wafers,disks, or reticles, comprising: a container comprising an openableenclosure, the container being formed to support, enclose and protectthe articles; and an at least partially transparent portion at leastpartially formed of a photochromic material that changes color ordarkness in response to exposure to electromagnetic radiation of aselected wavelength or range of wavelengths.
 2. The carrier as claimedin claim 2, in which the container comprises a case and a door
 3. Thecarrier as claimed in claim 2, in which the transparent portion is apart of the case.
 4. The carrier as claimed in claim 2, in which thetransparent portion is a part of the door.
 5. The carrier as claimed inclaim 1, in which the selected wavelength or range of wavelengthscomprises ultraviolet light.
 6. The carrier as claimed in claim 1, inwhich the selected wavelength or range of wavelengths comprises deepultraviolet light.
 7. The carrier as claimed in claim 2, in whichsubstantially the entire door is formed of the photochromic material. 8.The carrier as claimed in claim 2, in which substantially the entirecase is formed of the photochromic material.
 9. The carrier as claimedin claim 1, in which a window in the carrier is formed of thephotochromic material.
 10. A method for determining if a carrier fortransporting articles including semiconductor wafers, disks, or reticlesis exposed to undesired electromagnetic radiation comprising the stepsof: placing the articles in a container comprising an openableenclosure, the container being formed to support, enclose and protectthe articles; and an at least partially transparent portion at leastpartially formed of a photochromic material that changes color ordarkness in response to exposure to electromagnetic radiation of aselected wavelength or range of wavelengths; transporting the container;and observing the photochromic material to discern any change in coloror darkness.
 11. The method as claimed in claim 10, further comprisingthe step of selecting the wavelength to include ultraviolet light. 12.The method as claimed in claim 10, further comprising the step ofselecting the wavelength to include deep ultraviolet light.
 13. Themethod as claimed in claim 10, in which the in which the containercomprises a case and a door
 14. The carrier as claimed in claim 13, inwhich the transparent portion is a part of the case.
 15. The carrier asclaimed in claim 13, in which the transparent portion is a part of thedoor.
 16. A method for protecting articles including semiconductorwafers, disks, or reticles from exposure to undesired electromagneticradiation comprising the steps of: placing the articles in a containercomprising an openable enclosure, forming the container to support,enclose and protect the articles; and forming the container to includean least partially transparent portion at least partially formed of aphotochromic material that changes color or darkness in response toexposure to electromagnetic radiation of a selected wavelength or rangeof wavelengths.
 17. The method as claimed in claim 16, furthercomprising the step of selecting the photochromic material such that itchanges color or darkens to absorb or reflect the undesiredelectromagnetic radiation.
 18. The method as claimed in claim 16,further comprising the steps of observing the photochromic to discern achange in color or darkness; and acting to remove the container from theexposure to undesired electromagnetic radiation.
 19. The method asclaimed in claim 16, further comprising the step of selecting thewavelength to include ultraviolet light.
 20. The method as claimed inclaim 16, further comprising the step of selecting the wavelength toinclude deep ultraviolet light.
 21. The method as claimed in claim 16,in which the in which the container comprises a case and a door.
 22. Thecarrier as claimed in claim 21, in which the transparent portion is apart of the case.
 23. The carrier as claimed in claim 21, in which thetransparent portion is a part of the door.